CN111813700A - Monitoring data display method and device - Google Patents
Monitoring data display method and device Download PDFInfo
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- CN111813700A CN111813700A CN202010915947.0A CN202010915947A CN111813700A CN 111813700 A CN111813700 A CN 111813700A CN 202010915947 A CN202010915947 A CN 202010915947A CN 111813700 A CN111813700 A CN 111813700A
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- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F11/00—Error detection; Error correction; Monitoring
- G06F11/36—Preventing errors by testing or debugging software
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- G06F11/3688—Test management for test execution, e.g. scheduling of test suites
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- G06F11/00—Error detection; Error correction; Monitoring
- G06F11/30—Monitoring
- G06F11/34—Recording or statistical evaluation of computer activity, e.g. of down time, of input/output operation ; Recording or statistical evaluation of user activity, e.g. usability assessment
- G06F11/3438—Recording or statistical evaluation of computer activity, e.g. of down time, of input/output operation ; Recording or statistical evaluation of user activity, e.g. usability assessment monitoring of user actions
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- G06F3/00—Input arrangements for transferring data to be processed into a form capable of being handled by the computer; Output arrangements for transferring data from processing unit to output unit, e.g. interface arrangements
- G06F3/01—Input arrangements or combined input and output arrangements for interaction between user and computer
- G06F3/048—Interaction techniques based on graphical user interfaces [GUI]
- G06F3/0481—Interaction techniques based on graphical user interfaces [GUI] based on specific properties of the displayed interaction object or a metaphor-based environment, e.g. interaction with desktop elements like windows or icons, or assisted by a cursor's changing behaviour or appearance
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Abstract
The application provides a monitoring data display method and device for an intelligent traffic system, the intelligent traffic system comprises a front-end camera and a monitoring terminal with a screen, the monitoring terminal can divide a display interface corresponding to a test interface into at least two display areas with different operation heat degrees by acquiring historical trigger data triggered by each unit area in the test interface within a preset time length, further acquiring and marking each function control as a function control with different operation demand degrees according to historical use frequency data of each function control in a video monitoring function, and then displaying the function control corresponding to the operation demand degrees in the display areas with different operation heat degrees of the display interface according to the corresponding relation between the operation heat degrees and the operation demand degrees so as to display video monitoring data acquired by the front-end camera through the display function control in the function control and avoid the influence on interface operation caused by the fact that the display function control with low operation demand degree is displayed in the display area with high operation heat degree Efficiency.
Description
Technical Field
The application relates to the field of intelligent traffic, in particular to a monitoring data display method and device.
Background
With the explosion of the internet, visualization applications developed based on a C/S (Client/Server) architecture are ubiquitous, wherein video monitoring clients are involved.
In a traditional video monitoring client, a display interface of the traditional video monitoring client usually adopts a control combination mode to display controls, but the controls frequently used by a user are always dispersed in areas not frequently used by the user, for example, the operation controls frequently used by the user are scattered in each area, so that the operation efficiency of the user on the monitoring client interface is not high.
Therefore, the current monitoring data display technology has the technical problem of low interface operation efficiency caused by unreasonable control layout.
Disclosure of Invention
The embodiment of the application provides a monitoring data display method and device for an intelligent traffic system, which are used for solving the technical problem that the interface operation efficiency is not high due to unreasonable control layout in the current monitoring data display technology.
The embodiment of the application provides a monitoring data display method for an intelligent traffic system, wherein the intelligent traffic system comprises a front-end camera and a monitoring terminal with a screen, and the monitoring data display method comprises the following steps:
acquiring triggered historical trigger data of each unit area in a test interface within a preset time length, wherein the test interface is a test interface displayed on the screen;
dividing a display interface corresponding to the test interface into at least two display areas with different operation heat degrees according to the historical trigger data;
acquiring and marking each function control as a function control with different operation demand degrees according to historical use frequency data of each function control in the video monitoring function;
displaying a function control corresponding to the operation demand degree in display areas with different operation heat degrees of the display interface according to the corresponding relation between the operation heat degree and the operation demand degree;
and displaying the video monitoring data acquired by the front-end camera through a display function control in the function controls.
Simultaneously, this application embodiment still provides a control data display device for wisdom traffic system, should wisdom traffic system includes the front end camera and has the monitor terminal of screen, and this control data display device includes:
the data acquisition module is used for acquiring triggered historical trigger data of each unit area in a test interface within a preset time length, and the test interface is a test interface displayed on the screen;
the interface dividing module is used for dividing a display interface corresponding to the test interface into at least two display areas with different operation heat degrees according to the historical trigger data;
the control marking module is used for acquiring and marking each function control as a function control with different operation demand degrees according to historical use frequency data of each function control in the video monitoring function;
the control display module is used for displaying the functional controls corresponding to the operation demand degrees in the display areas with different operation heat degrees of the display interface according to the corresponding relation between the operation heat degrees and the operation demand degrees;
and the data display module is used for displaying the video monitoring data acquired by the front-end camera through a display function control in the function controls.
Meanwhile, the embodiment of the application also provides an electronic device, which comprises a memory and a processor; the memory stores an application program, and the processor is configured to run the application program in the memory to perform any one of the operations in the monitoring data presentation method.
Meanwhile, the embodiment of the application also provides a computer-readable storage medium for the intelligent transportation system, wherein a plurality of instructions are stored in the computer-readable storage medium, and the instructions are suitable for being loaded by a processor so as to execute the steps in the monitoring data display method.
Has the advantages that: the embodiment of the application provides a monitoring data display method and a device for an intelligent traffic system, the intelligent traffic system comprises a front-end camera and a monitoring terminal with a screen, the monitoring terminal can divide a display interface corresponding to a test interface into at least two display areas with different operation heat degrees by acquiring historical trigger data triggered in each unit area in the test interface within a preset time length, further acquiring and marking each function control as a function control with different operation demand degrees according to historical use frequency data of each function control in a video monitoring function, then displaying the function control corresponding to the operation demand degrees in the display areas with different operation heat degrees of the display interface according to the corresponding relation between the operation heat degrees and the operation demand degrees so as to display video monitoring data collected by the front-end camera through the display function control in the function control, the display function control with low operation demand degree is prevented from being displayed in the display area with high operation heat degree to influence the interface operation efficiency.
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The technical solution and other advantages of the present application will become apparent from the detailed description of the embodiments of the present application with reference to the accompanying drawings.
Fig. 1 is a scene schematic diagram of a monitoring data display method for an intelligent transportation system according to an embodiment of the present application.
Fig. 2 is a schematic flowchart of a monitoring data displaying method for an intelligent transportation system according to an embodiment of the present disclosure.
Fig. 3 (a) is a schematic view of a first test interface of a monitoring data displaying method according to an embodiment of the present application.
Fig. 3 (b) is a schematic view of a second test interface of the monitoring data displaying method according to the embodiment of the present application.
Fig. 3 (c) is a schematic view of a third test interface of the monitoring data displaying method according to the embodiment of the present application.
Fig. 3 (d) is a schematic view of a fourth test interface of the monitoring data displaying method according to the embodiment of the present application.
Fig. 4 (a) is a schematic diagram of an interface trigger effect of a test interface provided in the embodiment of the present application.
Fig. 4 (b) is a schematic diagram of an interface division effect of a display interface provided in the embodiment of the present application.
Fig. 5 is a first interface schematic diagram of a display interface provided in the embodiment of the present application.
Fig. 6 is a second interface schematic diagram of a display interface provided in the embodiment of the present application.
Fig. 7 is an interface schematic diagram of an initial display interface provided in an embodiment of the present application.
Fig. 8 (a) is a schematic diagram of a first area structure of an initial display interface according to an embodiment of the present application.
Fig. 8 (b) is a schematic diagram of a first area structure of a test interface according to an embodiment of the present application.
Fig. 9 (a) is a schematic diagram of a second area structure of an initial display interface according to an embodiment of the present application.
Fig. 9 (b) is a schematic diagram of a second area structure of the test interface provided in the embodiment of the present application.
Fig. 10 is a schematic structural diagram of a monitoring data display device according to an embodiment of the present application.
Fig. 11 is a schematic structural diagram of a computer device according to an embodiment of the present application.
Detailed Description
The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application. It is to be understood that the embodiments described are only a few embodiments of the present application and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.
In the embodiment of the application, the smart transportation refers to a transportation-oriented service system which fully utilizes modern electronic information technologies such as internet of things, cloud computing, artificial intelligence, automatic control, mobile internet and the like in the transportation field; the intelligent traffic system is a 'high-efficiency, safe, environment-friendly, comfortable and civilized' intelligent traffic and transportation system established by taking a national intelligent traffic system framework as guidance, greatly improves the management level and the operation efficiency of the urban traffic and transportation system, and provides all-round traffic information service and convenient, efficient, quick, economic, safe, humanized and intelligent traffic and transportation service for travelers.
In the embodiments of the present application, the word "for example" is used to mean "serving as an example, instance, or illustration. Any embodiment described herein as "for example" is not necessarily to be construed as preferred or advantageous over other embodiments. The following description is presented to enable any person skilled in the art to make and use the invention. In the following description, details are set forth for the purpose of explanation. It will be apparent to one of ordinary skill in the art that the present invention may be practiced without these specific details. In other instances, well-known structures and processes are not shown in detail to avoid obscuring the description of the invention with unnecessary detail. Thus, the present invention is not intended to be limited to the embodiments shown, but is to be accorded the widest scope consistent with the principles and features disclosed herein.
It should be noted that, since the method in the embodiment of the present application is executed in the monitoring terminals, the processing objects of each monitoring terminal exist in the form of data or information, for example, time, which is substantially time information, it can be understood that, in the subsequent embodiments, if the size, the number, the position, and the like are mentioned, corresponding data exist, so that the monitoring terminals perform processing, and details are not described herein.
The embodiment of the application provides a monitoring data display method and device for an intelligent traffic system, which are described in detail below.
Referring to fig. 1, fig. 1 is a schematic view of a scene of a monitoring data displaying method for an intelligent traffic system according to an embodiment of the present disclosure, where the system may include a front-end camera 11 and a monitoring terminal 12, and the front-end camera 11 and the monitoring terminal 12 may be connected and communicated through an internet formed by various gateways, such as a wide area network and a local area network, which are not described herein again. It is understood that the front-end camera 11 includes, but is not limited to, a camera of a front-end device such as an embedded high-definition video camera, an industrial personal computer, a high-definition camera, and the like, and is used for information acquisition, encoding, processing, storage, transmission, security control, and the like. The monitoring terminal 12 is a client device registered and authorized by the intelligent transportation system and having an operation demand on data and devices in the system, and may specifically include a client for a traffic police, a client for a developer, and the like, and the monitoring terminal 12 may be a device including receiving and transmitting hardware, that is, a device having receiving and transmitting hardware capable of performing bidirectional communication on a bidirectional communication link. Such a device may include: the cellular or other communication device, which may have a single line display or a multi-line display or may not have a multi-line display, may specifically be one of a desktop terminal or a mobile terminal, such as a mobile phone, a tablet computer, a notebook computer, etc.
It should be further noted that the scenario diagram of the intelligent traffic system shown in fig. 1 is only an example, and the intelligent traffic system and the scenario described in the embodiment of the present invention are for more clearly illustrating the technical solution of the embodiment of the present invention, and do not form a limitation on the technical solution provided in the embodiment of the present invention. The following are detailed below. It should be noted that the following description of the embodiments is not intended to limit the preferred order of the embodiments.
Referring to fig. 2, in one embodiment, a monitoring data display method for an intelligent traffic system is provided. The embodiment is mainly illustrated by applying the method to the monitoring terminal 12 in fig. 1. Referring to fig. 2, the monitoring data display method specifically includes steps S201 to S205, and specifically includes the following steps:
s201, acquiring triggered historical trigger data of each unit area in a test interface within a preset time length, wherein the test interface is the test interface displayed on the screen.
The preset time duration refers to a time duration for collecting the historical trigger data, and is, for example, 30 minutes, 2 hours, and the like. It can be understood that the preset time duration in this embodiment may be a time duration accumulated by taking the current computer time as a start time, or a time duration limited by a preset start-stop time.
The test interface is a test interface for collecting user interface operation data to generate a monitoring data display interface by using the data, and the monitoring data display interface can be a User Interface (UI) required for displaying monitoring data.
The unit area refers to the smallest area of the test interface that can be operated.
Specifically, the monitoring terminal 12 obtains historical trigger data triggered in each unit area in the test interface within a preset time length, and the historical trigger data can be realized through the test interface displayed on the screen of the monitoring terminal 12, the test interface can be a blank interface without control filling shown in fig. 3 (a) and 3 (b), or an interface with the same unit operation area uniformly distributed as shown in fig. 3 (c) and 3 (d), and both types of test interfaces can avoid influence on the judgment of the high-frequency and low-frequency trigger areas. Each unit area in the test interface can be triggered by a user's finger (as shown in fig. 3 (a) and 3 (c)), or by an input device having a pointer such as a mouse or a laser pointer (as shown in fig. 3 (b) and 3 (d)). The trigger operation for triggering each unit area may be at least one of a click operation, a double click operation, and a long press operation. After the user performs the trigger operation on each unit area in the test interface within the preset time, the monitoring terminal 12 may integrate and analyze all the trigger operations to obtain the historical trigger data.
For example, referring to fig. 3 (b), the test interface displayed on the screen of the monitoring terminal 12 is a blank interface, after the user uses a mouse to perform a click operation in any area of the blank interface, the monitoring terminal 12 may analyze the click operation to obtain corresponding trigger data (such as a trigger position), and if the user performs the trigger operation on the blank interface continuously or discontinuously within 24 hours of a preset time duration, the monitoring terminal 12 may obtain historical trigger data (such as trigger times and trigger positions) of the test interface triggered within the preset time duration.
It should be noted that, the user referred to in the embodiment of the present application may be a developer of the monitoring terminal 12, or may be an insider of a public security system.
And S202, dividing the display interface corresponding to the test interface into at least two display areas with different operation heat degrees according to the historical trigger data.
The display interface is an interface corresponding to the test interface and used for displaying and managing monitoring data, and the monitoring terminal 12 in different types (CS architecture or BS architecture), resolutions (1920 × 1080 and others) and application scenarios may use the same display interface as the test interface or a different display interface.
The display area refers to a relatively independent interface sub-area in the display interface.
The operation heat level is a degree to which the display region is operated, and the operation heat levels of different display regions may be calculated by the number of times of trigger operations per unit time or by a ratio of the number of times of trigger operations, for example, 20% or 80%.
Specifically, the monitoring terminal 12 divides the display interface corresponding to the test interface into at least two display areas with different operation heat degrees according to the historical trigger data, and before dividing the display areas, the operation heat degree of each area in the display interface, the number of the areas to be divided, and the number of the areas and the operation heat degree can be used for dividing the display areas. The acquiring step of the number of the areas comprises the following steps: classifying the function controls according to the types of the function controls to obtain a function control group; and acquiring the number of the groups of the function control groups as the number of the areas of the display area. After the number of the areas to be divided is determined, the area division can be carried out on the display interface, and the area division step comprises the following steps: determining the origin of coordinates of the display interface in a plane rectangular coordinate system; calculating a distance value between the coordinate of the operation point and the origin of the coordinate; and according to the distance value, carrying out region division on the display interface according to the region number to obtain the display region. The coordinates of the operation points in the step are coordinates of each operation point in the test interface under a rectangular plane coordinate system, and the operation points refer to position points of different trigger operations in the test interface. After the interface is divided into the display areas, each operation point falls into the corresponding display area, so that the display areas may include different numbers of operation points, and the number of the operation points included in each display area can be used as a basis for determining the operation heat.
For example, the historical trigger data at least includes a trigger position and a trigger frequency, where the trigger position is the above-mentioned operation point coordinate and is used to divide the display area; the number of triggering times is the number of the above-mentioned operation points, and is used for determining the operation heat of the display area, and the triggering position and the number of triggering times can be described in detail by fig. 4 (a) and 4 (b). Fig. 4 (a) is a schematic diagram of the trigger effect of the triggered test interface. The trigger position of the test interface triggered by the mouse is represented as the position of each dot shown in fig. 4 (a), and if the test interface is placed in a rectangular plane coordinate system, each dot can be regarded as the coordinate of the operation point. The number of times the test interface was triggered by the mouse is represented by the total number of dots shown in fig. 4 (a). As shown in fig. 4 (b), a schematic diagram of the region dividing effect is shown in which one display interface is divided. If the number of the regions is determined to be 4 in the previous step, the display interface corresponding to the test interface may be divided into 4 display regions as shown in fig. 4 (b), where the region (i) includes 6 triggered dots (operation points), the region (ii) includes 3 triggered dots, the region (iii) includes 2 triggered dots, and the region (iv) includes 1 triggered dot, and then the relationship between the operation heat degrees of the 4 display regions is as follows: the area (I) is greater than the area (II) is greater than the area (III).
The operation heat degree can be described by a numerical value, or can be described by a percentage, if the operation heat degree is described by the percentage, the larger the percentage numerical value is, the higher the operation heat degree is, if the operation heat degree is described by the percentage, the numerical value is based on an actual application scene, if the operation heat degree is described by the numerical value, the larger the numerical value is, the higher the operation heat degree is, or the smaller the numerical value is, the higher the operation heat degree is. For example, if the region (i) is triggered 6 times in 1 hour, the region (ii) is triggered 3 times in 1 hour, and the total number of times the test interface is triggered is 12 times, the operating heat of the region (i) is 50% and the operating heat of the region (ii) is 17%.
It should be noted that the number of the display areas may be set according to practical application requirements, and the embodiment of the present application only illustrates the processing manner when the number of the display areas is 4, and does not exclude that the number of the display areas is 3 or other embodiments, so the present application does not specifically limit the number of the display areas. Meanwhile, the acquisition mode of the number of the regions can be determined not only by the number of the functional control group, but also by the functional attributes, appearance styles, trigger modes and other factors of the functional controls. Therefore, the present application does not specifically limit the manner in which the number of display areas is acquired.
And S203, acquiring and marking each function control as a function control with different operation requirement degrees according to the historical use frequency data of each function control in the video monitoring function.
Video monitoring is an important component of a safety precaution system, and with the rapid development of computers, networks, image processing and transmission technologies, video monitoring technologies have been developed.
Wherein, a control refers to a component (visualization component) with a User Interface (UI), for example, a button, a list box, an edit box, or static text in a dialog box; a functionality control refers to a control having a specified utility.
The historical usage frequency data refers to the frequency of the function control used within a preset time period, for example, the number of uses within the past 24 hours is 5.
The operation requirement degree refers to a degree that the function control needs to be operated, and the operation requirement degrees of different function controls may be calculated according to the number of times of triggering operated in unit time, or may be calculated according to a ratio of the number of times of triggering, for example, 20% or 80%.
Specifically, the monitoring terminal 12 obtains historical use frequency data of each function control in the video monitoring function, and according to the historical use frequency data, marks each function control as a function control with a different operation demand degree, and determines that the basis of the operation demand degree is the historical use frequency data of each function control, where a larger numerical value in the historical use frequency data indicates a higher operation demand degree, and a smaller numerical value in the historical use frequency data indicates a lower operation demand degree. According to historical use frequency data, marking each function control in the video monitoring function with a dedicated operation demand degree, determining a display area of each function control in the display interface according to the operation demand degree, and filling the function control into the display area to obtain an updated display interface.
And S204, displaying the function control corresponding to the operation demand degree in the display areas with different operation heat degrees of the display interface according to the corresponding relation between the operation heat degrees and the operation demand degree.
Specifically, the correspondence between the operation heat and the operation demand may be set in the form of a preset table, and in order to fill the functional control with the high operation demand in the display area with the high operation heat, the technical problem that the interface operation efficiency is not high due to unreasonable layout of the control in the existing monitoring data display technology is solved. And after the control is filled, the function control corresponding to the operation demand degree can be displayed in the display areas with different operation heat degrees of the display interface.
For example, refer to fig. 5, which is a schematic interface diagram in which different display regions in a display interface are filled with different function controls. The display interface shown in fig. 5 is the display interface shown in fig. 4 (b), the display interface includes 4 divided display areas, and the operation heat degree size relationship of the 4 display areas is as follows: the area (I) is greater than the area (II) is greater than the area (III). Meanwhile, if the video monitoring function comprises the following functional controls: the mode function control, the selection function control, the auxiliary function control and the display function control, and the number of times that each function control is used in the past 24 hours in a preset time length is respectively as follows: the mode function control is 12 times, the function control is selected for 8 times, the auxiliary function control is 6 times, and the function control is displayed for 2 times, so that after the historical use frequency data of each function control is analyzed, the operation requirement degree size relationship of each function control can be determined as follows: mode function control > select function control > auxiliary function control > display function control. Therefore, corresponding to the high-to-high correspondence between the operation heat and the operation demand, the mode function control can be filled into the region (i), the selection function control can be filled into the region (ii), the auxiliary function control can be filled into the region (iii), and the display function control can be filled into the region (ii), so that the display interface having the interface layout corresponding to the operation heat and the operation demand as shown in fig. 5, that is, the updated display interface, can be finally obtained.
It should be noted that the function control may be an independent control, or a function control composed of a plurality of sub-controls, and the number of the function controls of the same type may be determined according to actual application requirements.
And S205, displaying the video monitoring data collected by the front-end camera through a display function control in the function controls.
The display function control is used for displaying video monitoring data, and the video monitoring data can be displayed in the display function control in the format of an image, a video or a motion picture.
Specifically, after the monitoring terminal 12 transmits the video monitoring data acquired by the front-end camera 11 to the display function control, the video monitoring data acquired by the front-end camera 11 can be displayed by the display function control, and since the video monitoring data acquired by the front-end camera 11 is monitoring data within a certain time range, the video monitoring data displayed in the display function control can be provided for a user to select by the mode function control in a data display period, and if the mode function control includes "real-time video" and "video playback", when the user triggers the "real-time video" mode, the real-time monitoring data currently acquired by the front-end camera 11 is displayed in the display function control; the user triggers a video playback mode, and historical monitoring data collected by the front-end camera 11 is displayed in the display function control.
More specifically, if there are a plurality of front-end cameras 11, the plurality of front-end cameras 11 all collect corresponding video monitoring data, so that the video monitoring data displayed in the display function control can be provided for a user to select a monitored object by selecting the function control, and if the selection function control includes "camera a" and "camera B", the user selects the "camera a" control, the video monitoring data collected by "camera a" is displayed in the display function control; and when the user selects the control of the camera B, displaying the video monitoring data collected by the camera B in the functional control. The angle adjustment of the real object image acquired by each front-end camera 11 can be provided for the user by the auxiliary function control, if the auxiliary function control comprises "move up" and "focus", when the user selects the "move up" control, the monitoring terminal 12 sends an instruction to instruct the front-end camera 11 to move up by a certain angle, and at this time, the video monitoring data displayed in the display function control changes to move up; when the user selects the "focus" control, the monitoring terminal 12 sends an instruction to instruct the front-end camera 11 to focus the currently acquired physical object, and at this time, the video monitoring data displayed in the display function control changes to focus on one point.
For example, refer to fig. 6, which is a schematic diagram illustrating an interface effect of a display interface displaying video monitoring data. As shown in fig. 6, the mode function control, the selection function control, the auxiliary function control, and the display function control may be added or deleted in the corresponding display area in the display interface based on the above example, and the display function control may be used to display only the video monitoring data acquired by one front-end camera, or may simultaneously display the video monitoring data acquired by a plurality of front-end cameras. Since the function controls "interface minimize", "interface restore down", and "interface close" belong to controls with a high degree of operation demand, the three function controls can be filled in the region of high operation heat (r).
It should be noted that each function control is further configured with a display resource, the display resource includes a color, a size, a map, a frame style, and the like of the function control displayed in the display area, and the display resource may be associated and bound with each function control in advance, so that the display resource can be loaded and used correspondingly when the monitoring terminal 12 enables each function control, and is finally presented in the display interface.
According to the monitoring data display method, the monitoring terminal can divide the display interface corresponding to the test interface into at least two display areas with different operation heat degrees by acquiring the triggered historical trigger data of each unit area in the test interface within the preset time length, further acquire and mark each function control as the function control with different operation heat degrees according to the historical use frequency data of each function control in the video monitoring function, and then display the function control corresponding to the operation heat degrees in the display areas with different operation heat degrees of the display interface according to the corresponding relation between the operation heat degrees and the operation heat degrees so as to display the video monitoring data collected by the front-end camera through the display function control in the function control, thereby avoiding the influence on the interface operation efficiency caused by the display function control with low operation heat degree displayed in the display area with high operation heat degree.
In one embodiment, step S201 specifically includes the following steps:
s301, acquiring an initial display interface corresponding to the monitoring terminal;
s302, generating the test interface according to the initial display interface;
s303, displaying the test interface on the monitoring terminal;
s304, obtaining a statistical result of triggered triggering behaviors of each unit area in the test interface within the preset time length to obtain the historical triggering data, wherein the triggering behaviors comprise at least one of an interface click behavior, an interface double-click behavior, an interface long-press behavior and a gesture sensing behavior.
The initial display interface may refer to a display interface of an initial version, but the initial display interface has a problem of unreasonable control layout, and an interface schematic diagram of the initial display interface may refer to fig. 7, which is greatly different from the updated display interface shown in fig. 6 in interface layout.
The interface click behavior, the interface double click behavior and the interface long press behavior are interface touch behaviors, the gesture sensing behavior is a non-interface touch behavior, the gesture sensing behavior is acquired by means of a gesture sensing camera connected with the monitoring terminal 12, gesture changes of the user are collected based on the gesture sensing camera, and the gesture sensing behavior of the user can be determined.
Specifically, before the monitor terminal 12 displays the test interface on the screen, an initial display interface is displayed first, specifically referring to fig. 7, where the initial display interface shown in fig. 7 may be understood as a conventional display interface, in the conventional display interface, all function controls are distributed in various interface regions in a disordered manner, so that the interface operation is messy, the function use is complex, and the operation efficiency of the user on the interface is easily affected. In order to solve the problem, the application proposes to generate a test interface corresponding to the updatable display interface based on the initial display interface, and further acquire historical trigger data generated by triggering in the test interface by a user by using the test interface, so as to analyze high and low frequency operation areas of the interface by using the historical trigger data, namely, the display areas with different operation heat degrees mentioned in the above embodiments. The high-frequency operation function control is placed in the high-frequency operation area, so that the operation path of a user in the interface can be saved and shortened, the interface operation time is saved, and the interface operation efficiency is improved.
More specifically, when the monitoring terminal 12 obtains the statistical result of the trigger behaviors triggered in each unit area in the test interface within the preset time length, the trigger behaviors include an interface click behavior, an interface double click behavior, an interface long press behavior, and a gesture sensing behavior, and the monitoring terminal 12 may determine the trigger point coordinates of each trigger behavior in the test interface, so the statistical result of the trigger behavior may include a coordinate average value between at least two trigger point coordinates, that is, a trigger point average value coordinate, where the trigger point average value coordinate is a circular point shown in fig. 4 (a).
In one embodiment, the test interface includes a blank interface, and the step S302 specifically includes the following steps:
s401, when all areas in the initial display interface are effective operation areas, acquiring the size of an interface frame of the initial display interface;
s402, constructing an interface with the same size as the interface frame as the test interface based on the size of the interface frame.
The effective operation area refers to an interface area which can be filled with the function control for the user to operate.
Specifically, when the monitoring terminal 12 generates the test interface according to the initial display interface, if all the areas in the initial display interface are valid operation areas, that is, the entire area of the initial display interface can be used for filling the function control, only the size of the interface frame displayed by the initial display interface in the screen of the monitoring terminal 12 needs to be obtained, and then the test interface with the same size is constructed based on the size of the interface frame, so that the test interface with the same size as the initial display interface is used for optimizing the final display interface. It is understood that the size of the interface frame may be the size of the initial display interface relative to the size of the screen of the monitoring terminal 12, or may be the coordinate area of the initial display interface in the rectangular coordinate system of the plane where the screen is located.
In one embodiment, the test interface includes a blank interface, and the step S302 specifically includes the following steps:
s501, when an invalid operation area exists in the initial display interface, acquiring the size and the position of the valid operation area in the initial display interface and the size of an interface frame of the initial display interface;
s502, constructing a test interface corresponding to the size of the interface frame according to the size of the interface frame of the initial display interface;
s503, determining the size and the position of an effective acquisition area for acquiring historical trigger data in the test interface according to the size and the position of the effective operation area.
The invalid operation area refers to an interface area which cannot be filled with the function control for the user to operate.
Specifically, when the monitoring terminal 12 generates the test interface according to the initial display interface, if not only an effective operation region but also an invalid operation region exists in the initial display interface, that is, a part of the region in the initial display interface cannot be used for filling the function control, only the effective operation region needs to be analyzed. When generating the test interface, firstly, according to the size of the interface frame of the initial display interface, constructing a test interface with the same size as the initial display interface, and further determining the size and the position of an effective acquisition area which can be used for acquiring historical trigger data by using the size and the position of the effective operation area in the test interface of the existing interface frame. It should be noted that the size and position of the effective acquisition area in the test interface may be equal to the size and position of the effective operation area in the initial display interface. It is understood that the size and location of the area can only be relative to the size and location of the interface, which can be relative to the size and display location of the screen of the monitor terminal 12.
For example, referring to fig. 8 (a) and 8 (b), when the test interface is set as a blank interface, an interface schematic diagram of the test interface is generated according to the initial display interface. As shown in fig. 8 (a), the initial display interface includes an effective operation area and an ineffective operation area, and since the ineffective operation area in the initial display interface cannot be filled with the function control, the updated display interface will have the same area that cannot be operated, and the test interface used by the updated display interface is optimized, and the same area cannot be used for collecting the historical trigger data, whereas the effective operation area of the initial display interface is opposite to the effective operation area.
In one embodiment, the test interface includes an interface with the same unit operation areas uniformly distributed thereon, and the step S302 specifically includes the following steps:
s601, determining the size of a function control in the initial display interface;
s602, when all areas in the initial display interface are effective operation areas, acquiring the size of an interface frame of the initial display interface;
s603, constructing an interface with the same size as the interface frame as the test interface based on the size of the interface frame;
s604, determining the display area of the unit operation area in the test interface according to the size of the function control.
Specifically, when the monitor terminal 12 generates the test interface according to the initial display interface, if the required test interface is an interface in which the same unit operation regions are uniformly distributed, not only a test interface with the same interface frame size as the initial display interface needs to be constructed, and the validity of the operation regions in the initial display interface needs to be analyzed to avoid the influence of the invalid operation regions on the historical trigger data acquisition, but also the display area of the unit operation regions in the test interface needs to be correspondingly determined according to the size of each function control in the initial display interface, and the display area of the unit operation regions can be determined by the size of the function control in the initial display interface, that is, when the test interface is generated by the initial display interface, the function controls in the initial display interface can be converted into the unit operation regions in the test interface in the same size.
In one embodiment, the test interface includes an interface with the same unit operation areas uniformly distributed thereon, and the step S302 specifically includes the following steps:
s701, determining the size of a function control in the initial display interface;
s702, when an invalid operation area exists in the initial display interface, acquiring the size and the position of the valid operation area in the initial display interface and the size of an interface frame of the initial display interface;
s703, constructing a test interface corresponding to the size of the interface frame according to the size of the interface frame of the initial display interface;
s704, determining the size and the position of an effective acquisition area for acquiring historical trigger data in the test interface according to the size and the position of the effective operation area;
s705, determining the display area of the unit operation area in the effective acquisition area according to the size of the function control.
Specifically, when the monitoring terminal 12 generates the test interface according to the initial display interface, if the required test interface is an interface in which the same unit operation regions are uniformly distributed, based on the description of the above embodiment, it is necessary to construct a test interface having the same interface frame size as the initial display interface, analyze the validity of the operation regions in the initial display interface, and correspondingly determine the display area of the unit operation regions in the test interface according to the size of each function control in the initial display interface. However, different from the previous embodiment, in the embodiment, when an invalid operation area exists in the initial display interface, compared with a case where all areas of the initial display interface are valid operation areas, the influence of the invalid operation area on the subsequent historical trigger data acquisition needs to be avoided, so that not only a test interface with an equal size needs to be constructed according to the size of the interface frame of the initial display interface, but also the size and the position of the valid acquisition area in the test interface are further determined by using the size and the position of the valid operation area in the initial display interface based on the test interface with the determined size of the interface frame, so as to acquire the historical trigger data by using the valid acquisition area.
For example, referring to fig. 9 (a) and 9 (b), when the same unit operation regions are uniformly distributed on the test interface, the interface schematic diagram of the test interface is generated according to the initial display interface. As shown in fig. 9 (a), the initial display interface includes an effective operation area and an ineffective operation area, and since the ineffective operation area in the initial display interface cannot be filled with the function control, the updated display interface will have the same area that cannot be operated, the test interface used by the updated display interface is optimized, the same area cannot be used for collecting the historical trigger data, and the effective operation area of the initial display interface is the opposite.
In one embodiment, step S204 specifically includes the following steps:
s801, acquiring the number of areas of the display area;
s802, grouping the function controls according to the number of the areas and the operation demand degree to obtain a corresponding number of function control groups;
s803, determining the display area of the function control group in the display interface according to the corresponding relation between the operation demand degree and the operation heat degree;
s804, displaying the function controls in the function control group in the display area.
Specifically, the monitoring terminal 12 displays the function controls corresponding to the operation demand degree in the display area of the display interface according to the corresponding relationship between the operation heat degree and the operation demand degree, the display area to which each function control belongs needs to be determined before the function controls are displayed, and when the video monitoring function includes at least two function controls, the monitoring terminal 12 needs to group all the function controls to obtain function control groups matched with the number of the areas, and then each function control group is respectively filled into the corresponding display area, so that each display area in the display interface can display the corresponding function control.
More specifically, the manner of acquiring the number of regions has been described in detail in the above embodiments, and is not described herein again. The number of the regions can be used for determining the number of the groups of the function control groups, and the operation demand degree can be used as a grouping basis for the function controls. It should be noted that, if the number of the function controls is exactly equal to the number of the regions, each function control can be respectively filled into the display region to which it belongs according to the corresponding relationship; if the number of the function controls is larger than the number of the regions, the function controls can be grouped according to the operation requirement of each function control in combination with the actual application requirement, for example, the current function controls comprise a function control 1, a function control 2 and a function control 3, the number of the regions is 2, the number of the function controls is larger than the number of the regions, the number of the function controls is odd, the number of the regions is even, if the region areas of the two display regions are equal, the function controls can be grouped only according to the operation requirement, that is, the function controls with similar operation requirement are divided into one group, and the other function control is one group and correspondingly filled into the belonging display region. It can be understood that, since the operation heat and the operation requirement are both in a one-to-one correspondence relationship, if there is a case where the function control group includes more than one function control, an average value or a sum of all the operation requirement in the function control group may be calculated, a display area to which the function control group belongs may be determined according to the average value or the sum of the operation requirement, and the selection of the average value and the sum may be determined according to actual application requirements.
Further, if the number of the function controls is greater than the number of the regions, the number of the function controls is even, and the number of the regions is odd, the function controls can be grouped according to the operation requirement when the region area of the display region is large; when the area areas of the display areas are not equal to each other, more function controls are considered to be allocated to the display area with the largest area. If the number of the function controls is smaller than the number of the regions, the display regions to which the function controls belong are determined according to the corresponding relationship between the operation demand degree and the operation heat degree and then the corresponding display regions are used for displaying the function controls no matter the number of the function controls is odd or even.
Further, a server connected to the monitoring terminal 12 through a network, where the server responds to the request of the monitoring terminal 12, and the specific step of determining the display area to which the function control group belongs may be: receiving a function starting request sent by a monitoring terminal aiming at the video monitoring function; responding to the function starting request, and acquiring a function list corresponding to the video monitoring function and pre-stored in advance, wherein the function list comprises at least two functions; and feeding back the function list to the monitoring terminal so that the monitoring terminal classifies the functions in the function list and further determines the display area to which each function belongs.
In one embodiment, step S204 specifically includes the following steps:
s901, classifying the function controls according to the types of the function controls to obtain a function control group; the function control group comprises a mode function control, a selection function control, an auxiliary function control and a display function control;
s902, counting the total operation demand degree of the function control group;
s903, determining a display area of the function control component in the display interface according to the corresponding relation between the total operation demand degree and the operation heat degree;
and S904, displaying the function controls in the function control group in the display area.
The type of the function control may refer to a use attribute of the function control, such as a display function control for displaying data, an operation function control for operating data, and the like.
Specifically, when the monitor terminal 12 displays the function controls by using the display area, it may consider that the function controls are firstly grouped according to the size of the operation requirement degree mentioned in the previous embodiment, or the area of the display area, but the function controls are classified and grouped according to the type of the function controls, so as to obtain at least one type of function control group. And then counting the sum of the operation demand degrees of each group of function control groups, determining the display area to which each function control group belongs by using the corresponding relation between the total operation demand degree and the operation heat degree after obtaining the total operation demand degree, and finally displaying the corresponding function control group based on the display area to which the function control group belongs.
For example, after the function controls of the current video monitoring function are classified, four function control groups can be obtained: after the mode function control, the selection function control, the auxiliary function control and the display function control are determined according to the total operation requirement of each group of function controls, the corresponding function control group can be displayed in the display area, and the interface schematic diagrams displayed in the display interface by the four groups of function control groups can refer to fig. 5 to 6.
In one embodiment, step S904 specifically includes the following steps:
s1001, acquiring operation heat of different sub-display areas in each display area;
s1002, acquiring the operation demand degree of each function control in each function control group;
s1003, determining a sub-display area of each function control in the function control group in the corresponding display area according to the corresponding relation between the operation demand degree and the operation heat degree;
and S1004, correspondingly displaying the function control in the sub-display area.
The sub-display area may refer to a unit area in the display area, that is, a minimum area that can be operated, and the sub-display area may be used to fill the function control.
Specifically, referring to fig. 5, after the monitor terminal 12 determines the display area to which each group of function control groups belongs, if any function control group includes more than one function control, the display area to which the function control group belongs needs to be further analyzed, that is, the arrangement style of the function controls in the display area is determined, and the specific analysis step may include: the method comprises the steps of obtaining operation heat degrees of different sub-display areas in each display area, obtaining operation demand degrees of each function control in each function control group, determining the sub-display area to which each function control belongs in the display area to which each function control belongs based on the corresponding relation between the operation heat degrees of the sub-display areas and the operation demand degrees of the function controls, and correspondingly displaying the function controls in the sub-display areas.
For example, referring to fig. 6, the mode function control includes "real-time video" and "video playback", the selection function control includes "camera a" and "camera B", the display region to which the mode function control belongs may be known as region i in combination with fig. 5, and the display region to which the selection function control belongs may be known as region ii in combination with fig. 5, after the display region to which the function control group belongs is determined, since both the two groups of function control groups include 2 function controls, the operation heat of the respective sub-display regions of the region i and the region ii needs to be analyzed, and then the operation demand of the "real-time video", "video playback", "camera a", and "camera B" is correspondingly analyzed to determine the sub-display region of each function control in the display region to which the function control belongs, and finally the function control is displayed in the corresponding sub-display region. If the operation demand degree of the real-time video is 20%, the operation demand degree of the video playback is 15%, and the operation heat degree of the sub-region 1 in the region (i) is higher than that of the sub-region 2, it can be determined that the sub-display region of the real-time video function control is the sub-region 1, the sub-display region of the video playback function control is the sub-region 2, and the interface effect of the function control in the corresponding display mode in the sub-display region can refer to fig. 6.
The embodiment provides a monitoring data display method for an intelligent traffic system, and the display interface required for displaying video monitoring data can be adjusted to an optimal state based on the method, so that the operation path of the display interface is shortened, the operation time is saved, and the technical problem of low interface operation efficiency caused by unreasonable interface control layout in the existing monitoring data display technology is solved.
On the basis of the method in the foregoing embodiment, the present embodiment will be further described from the perspective of a monitoring data display device, please refer to fig. 10, where fig. 10 specifically describes the monitoring data display device provided in the present embodiment, which may include:
the data acquisition module 110 is configured to acquire triggered historical trigger data of each unit area in a test interface within a preset time duration, where the test interface is a test interface displayed on the screen;
the interface dividing module 120 is configured to divide the display interface corresponding to the test interface into at least two display areas with different operation heat degrees according to the historical trigger data;
the control marking module 130 is configured to obtain and mark each function control as a function control with different operation requirement degrees according to historical use frequency data of each function control in the video monitoring function;
the control display module 140 is configured to display a function control corresponding to the operation demand degree in display areas with different operation heat degrees on the display interface according to the correspondence between the operation heat degrees and the operation demand degrees;
and the data display module 150 is configured to display the video monitoring data acquired by the front-end camera through a display function control in the function controls.
In an embodiment, the data obtaining module 110 is further configured to obtain an initial display interface corresponding to the monitoring terminal; generating the test interface according to the initial display interface; displaying the test interface on the monitoring terminal; and obtaining a statistical result of triggered triggering behaviors of each unit area in the test interface within the preset time length to obtain the historical triggering data, wherein the triggering behaviors comprise at least one of an interface click behavior, an interface double click behavior, an interface long press behavior and a gesture sensing behavior.
In an embodiment, the test interface includes a blank interface, and the data obtaining module 110 is further configured to obtain an interface frame size of the initial display interface when all the areas in the initial display interface are valid operation areas; and constructing an interface with the same size as the interface frame as the test interface based on the size of the interface frame.
In an embodiment, the test interface includes a blank interface, and the data obtaining module 110 is further configured to, when an invalid operation area exists in the initial display interface, obtain a size and a position of the valid operation area in the initial display interface and an interface frame size of the initial display interface; constructing a test interface corresponding to the size of the interface frame according to the size of the interface frame of the initial display interface; and determining the size and the position of an effective acquisition area for acquiring historical trigger data in the test interface according to the size and the position of the effective operation area.
In an embodiment, the test interface includes an interface with the same unit operation areas uniformly distributed thereon, and the data obtaining module 110 is further configured to determine the size of the functional control in the initial display interface; when all areas in the initial display interface are effective operation areas, acquiring the size of an interface frame of the initial display interface; constructing an interface with the same size as the interface frame as the test interface based on the size of the interface frame; and determining the display area of a unit operation area in the test interface according to the size of the function control.
In an embodiment, the test interface includes an interface with the same unit operation areas uniformly distributed thereon, and the data obtaining module 110 is further configured to determine the size of the functional control in the initial display interface; when an invalid operation area exists in the initial display interface, acquiring the size and the position of the valid operation area in the initial display interface and the size of an interface frame of the initial display interface; constructing a test interface corresponding to the size of the interface frame according to the size of the interface frame of the initial display interface; determining the size and the position of an effective acquisition area for acquiring historical trigger data in the test interface according to the size and the position of the effective operation area; and determining the display area of a unit operation area in the effective acquisition area according to the size of the function control.
In one embodiment, the control display module 140 is further configured to obtain the number of areas of the display area; grouping the function controls according to the number of the areas and the operation demand degree to obtain a corresponding number of function control groups; determining a display area of the function control group in the display interface according to the corresponding relation between the operation demand degree and the operation heat degree; and displaying the function controls in the function control group in the display area.
In an embodiment, the control display module 140 is further configured to classify the function controls according to the types of the function controls, so as to obtain a function control group; the function control group comprises a mode function control, a selection function control, an auxiliary function control and a display function control; counting the total operation demand degree of the function control group; determining a display area of the function control assembly in the display interface according to the corresponding relation between the total operation demand degree and the operation heat degree; and displaying the function controls in the function control group in the display area.
In an embodiment, the control display module 140 is further configured to obtain operation heat of different sub-display areas in each display area; acquiring the operation demand degree of each function control in each function control group; determining a sub-display area of each function control in the function control group in the corresponding display area according to the corresponding relation between the operation demand degree and the operation heat degree; and correspondingly displaying the function control in the sub-display area.
In the above embodiment, a monitoring data display device for an intelligent traffic system is provided, and by adopting the device, a display function control with low operation demand can be prevented from being displayed in a display area with high operation heat, so that the interface operation efficiency is improved.
In summary, for the specific limitations of the monitoring data displaying apparatus, reference may be made to the above limitations of the monitoring data displaying method, which is not described herein again. The modules in the monitoring data display device can be wholly or partially realized by software, hardware and a combination thereof. The modules can be embedded in a hardware form or independent from a processor in the computer device, and can also be stored in a memory in the computer device in a software form, so that the processor can call and execute operations corresponding to the modules.
In one embodiment, the present application further provides a computer device, which may be a monitoring terminal, and its internal structure diagram may be as shown in fig. 11. The computer device includes a processor, a memory, a communication interface, a display screen, and an input device connected by a system bus. Wherein the processor of the computer device is configured to provide computing and control capabilities. The memory of the computer device comprises a nonvolatile storage medium and an internal memory. The non-volatile storage medium stores an operating system and a computer program. The internal memory provides an environment for the operation of an operating system and computer programs in the non-volatile storage medium. The communication interface of the computer device is used for carrying out wired or wireless communication with an external terminal, and the wireless communication can be realized through WIFI, an operator network, NFC (near field communication) or other technologies. The computer program is executed by a processor to implement a method of monitoring data presentation. The display screen of the computer equipment can be a liquid crystal display screen or an electronic ink display screen, and the input device of the computer equipment can be a touch layer covered on the display screen, a key, a track ball or a touch pad arranged on the shell of the computer equipment, an external keyboard, a touch pad or a mouse and the like.
Those skilled in the art will appreciate that the architecture shown in fig. 11 is merely a block diagram of some of the structures associated with the disclosed aspects and is not intended to limit the computing devices to which the disclosed aspects apply, as particular computing devices may include more or less components than those shown, or may combine certain components, or have a different arrangement of components.
In the foregoing embodiments, the descriptions of the respective embodiments have respective emphasis, and for parts that are not described in detail in a certain embodiment, reference may be made to related descriptions of other embodiments.
It will be understood by those skilled in the art that all or part of the steps of the methods of the above embodiments may be performed by instructions or by associated hardware controlled by the instructions, which may be stored in a computer readable storage medium and loaded and executed by a processor.
To this end, the present application provides a storage medium, in which a plurality of instructions are stored, and the instructions can be loaded by a processor to implement the following functions:
acquiring triggered historical trigger data of each unit area in a test interface within a preset time length, wherein the test interface is a test interface displayed on the screen; dividing a display interface corresponding to the test interface into at least two display areas with different operation heat degrees according to the historical trigger data; acquiring and marking each function control as a function control with different operation demand degrees according to historical use frequency data of each function control in the video monitoring function; displaying a function control corresponding to the operation demand degree in display areas with different operation heat degrees of the display interface according to the corresponding relation between the operation heat degree and the operation demand degree; and displaying the video monitoring data acquired by the front-end camera through a display function control in the function controls.
Wherein the storage medium may include: read Only Memory (ROM), Random Access Memory (RAM), magnetic or optical disks, and the like.
Since the instructions stored in the storage medium can execute the steps in any method provided in the embodiments of the present application, the beneficial effects that can be achieved by any method provided in the embodiments of the present application can be achieved, for details, see the foregoing embodiments, and are not described herein again.
The monitoring data display method and device for the intelligent traffic system provided by the embodiment of the application are introduced in detail, a specific example is applied in the description to explain the principle and the implementation of the application, and the description of the embodiment is only used for helping to understand the technical scheme and the core idea of the application; those of ordinary skill in the art will understand that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications or substitutions do not depart from the spirit and scope of the present disclosure as defined by the appended claims.
Claims (10)
1. A monitoring data display method for an intelligent traffic system is characterized in that the intelligent traffic system comprises a front-end camera and a monitoring terminal with a screen, the monitoring terminal is connected with the front-end camera in a wireless connection mode, the monitoring data display method is applied to the monitoring terminal, and the monitoring data display method comprises the following steps:
acquiring triggered historical trigger data of each unit area in a test interface within a preset time length, wherein the test interface is a test interface displayed on the screen;
dividing a display interface corresponding to the test interface into at least two display areas with different operation heat degrees according to the historical trigger data;
acquiring and marking each function control as a function control with different operation demand degrees according to historical use frequency data of each function control in the video monitoring function;
displaying a function control corresponding to the operation demand degree in display areas with different operation heat degrees of the display interface according to the corresponding relation between the operation heat degree and the operation demand degree;
and displaying the video monitoring data acquired by the front-end camera through a display function control in the function controls.
2. The method as claimed in claim 1, wherein the step of obtaining the trigger history data triggered in each unit area of the test interface within a predetermined time period comprises:
acquiring an initial display interface corresponding to the monitoring terminal;
generating the test interface according to the initial display interface;
displaying the test interface on the monitoring terminal;
and obtaining a statistical result of triggered triggering behaviors of each unit area in the test interface within the preset time length to obtain the historical triggering data, wherein the triggering behaviors comprise at least one of an interface click behavior, an interface double click behavior, an interface long press behavior and a gesture sensing behavior.
3. The method according to claim 2, wherein the test interface includes a blank interface, and the step of generating the test interface according to the initial display interface includes:
when all areas in the initial display interface are effective operation areas, acquiring the size of an interface frame of the initial display interface;
and constructing an interface with the same size as the interface frame as the test interface based on the size of the interface frame.
4. The method according to claim 2, wherein the test interface includes a blank interface, and the step of generating the test interface according to the initial display interface includes:
when an invalid operation area exists in the initial display interface, acquiring the size and the position of the valid operation area in the initial display interface and the size of an interface frame of the initial display interface;
constructing a test interface corresponding to the size of the interface frame according to the size of the interface frame of the initial display interface;
and determining the size and the position of an effective acquisition area for acquiring historical trigger data in the test interface according to the size and the position of the effective operation area.
5. The monitoring data display method for the intelligent transportation system according to claim 2, wherein the test interface includes interfaces with the same unit operation areas distributed uniformly, and the step of generating the test interface according to the initial display interface includes:
determining the size of a function control in the initial display interface;
when all areas in the initial display interface are effective operation areas, acquiring the size of an interface frame of the initial display interface;
constructing an interface with the same size as the interface frame as the test interface based on the size of the interface frame;
and determining the display area of a unit operation area in the test interface according to the size of the function control.
6. The monitoring data display method for the intelligent transportation system according to claim 2, wherein the test interface includes interfaces with the same unit operation areas distributed uniformly, and the step of generating the test interface according to the initial display interface includes:
determining the size of a function control in the initial display interface;
when an invalid operation area exists in the initial display interface, acquiring the size and the position of the valid operation area in the initial display interface and the size of an interface frame of the initial display interface;
constructing a test interface corresponding to the size of the interface frame according to the size of the interface frame of the initial display interface;
determining the size and the position of an effective acquisition area for acquiring historical trigger data in the test interface according to the size and the position of the effective operation area;
and determining the display area of a unit operation area in the effective acquisition area according to the size of the function control.
7. The method according to any one of claims 1 to 6, wherein the step of displaying the functionality control in the display area of the display interface according to the correspondence between the operation heat degree and the operation demand degree includes:
acquiring the number of the areas of the display area;
grouping the function controls according to the number of the areas and the operation demand degree to obtain a corresponding number of function control groups;
determining a display area of the function control group in the display interface according to the corresponding relation between the operation demand degree and the operation heat degree;
and displaying the function controls in the function control group in the display area.
8. The method according to any one of claims 1 to 6, wherein the step of displaying the functionality control in the display area of the display interface according to the correspondence between the operation heat degree and the operation demand degree includes:
classifying the function controls according to the types of the function controls to obtain a function control group; the function control group comprises a mode function control, a selection function control, an auxiliary function control and a display function control;
counting the total operation demand degree of the function control group;
determining a display area of the function control assembly in the display interface according to the corresponding relation between the total operation demand degree and the operation heat degree;
and displaying the function controls in the function control group in the display area.
9. The monitoring data presentation method for the intelligent transportation system according to claim 8, wherein the step of displaying the function controls in the function control group in the display area includes:
acquiring the operation heat of different sub-display areas in each display area;
acquiring the operation demand degree of each function control in each function control group;
determining a sub-display area of each function control in the function control group in the corresponding display area according to the corresponding relation between the operation demand degree and the operation heat degree;
and correspondingly displaying the function control in the sub-display area.
10. The utility model provides a control data display device for wisdom traffic system, a serial communication port, wisdom traffic system includes the front end camera and has the monitor terminal of screen, monitor terminal passes through wireless connection's mode and connects the front end camera, control data display device set up in among the monitor terminal, control data display device includes:
the data acquisition module is used for acquiring triggered historical trigger data of each unit area in a test interface within a preset time length, and the test interface is a test interface displayed on the screen;
the interface dividing module is used for dividing a display interface corresponding to the test interface into at least two display areas with different operation heat degrees according to the historical trigger data;
the control marking module is used for acquiring and marking each function control as a function control with different operation demand degrees according to historical use frequency data of each function control in the video monitoring function;
the control display module is used for displaying the functional controls corresponding to the operation demand degrees in the display areas with different operation heat degrees of the display interface according to the corresponding relation between the operation heat degrees and the operation demand degrees;
and the data display module is used for displaying the video monitoring data acquired by the front-end camera through a display function control in the function controls.
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